|
The
Story
of
Fluoridation
It
started
as
an
observation,
that
soon
took
the
shape
of
an
idea.
It
ended,
five
decades
later,
as
a
scientific
revolution
that
shot
dentistry
into
the
forefront
of
preventive
medicine.
This
is
the
story
of
how
dental
science
discovered-and
ultimately
proved
to
the
world-that
fluoride,
a
mineral
found
in
rocks
and
soil,
prevents
tooth
decay.Although
dental
caries
remains
a
public
health
worry,
it
is
no
longer
the
unbridled
problem
it
once
was,
thanks
to
fluoride.
A
Mysterious
Disorder
In
1909
Dr.
McKay
(r)
persuaded
the
Colorado
State
Dental
Association
to
invite
Dr.
Green
Vardiman
Black
(l),
one
of
the
nation's
most
eminent
dental
researchers,
to
attend
1909
convention
where
McKay's
findings
were
to
be
presented.
The
two
men
began
joint
research
and
discovered
other
areas
of
the
country
where
brown
staining
of
teeth
occured.
Fluoride
research
had
its
beginnings
in
1901,
when
a
young
dental
school
graduate
named
Frederick
McKay
left
the
East
Coast
to
open
a
dental
practice
in
Colorado
Springs,
Colorado.
When
he
arrived,
McKay
was
astounded
to
find
scores
of
Colorado
Springs
natives
with
grotesque
brown
stains
on
their
teeth.
So
severe
could
these
permanent
stains
be,
in
fact,
sometimes
entire
teeth
were
splotched
the
color
of
chocolate
candy.McKay
searched
in
vain
for
information
on
this
bizarre
disorder.
He
found
no
mention
of
the
brown-stained
teeth
in
any
of
the
dental
literature
of
the
day.
Local
residents
blamed
the
problem
on
any
number
of
strange
factors,
such
as
eating
too
much
pork,
consuming
inferior
milk,
and
drinking
calcium-rich
water.Thus,
McKay
took
up
the
gauntlet
and
initiated
research
into
the
disorder
himself.
His
first
epidemiological
investigations
were
scuttled
by
a
lack
of
interest
among
most
area
dentists.
But
McKay
persevered
and
ultimately
interested
local
practitioners
in
the
problem,
which
was
known
as
Colorado
Brown
Stain.
A
Fruitful
Collaboration
McKay's
first
big
break
came
in
1909,
when
renowned
dental
researcher
Dr.
G.V.
Black
agreed
to
come
to
Colorado
Springs
and
collaborate
with
him
on
the
mysterious
ailment.
Black,
who
had
previously
scoffed
that
it
was
impossible
such
a
disorder
could
go
unreported
in
the
dental
literature,
was
lured
West
shortly
after
the
Colorado
Springs
Dental
Society
conducted
a
study
showing
that
almost
90
percent
of
the
city's
locally
born
children
had
signs
of
the
brown
stains.When
Black
arrived
in
the
city,
he
too
was
shocked
by
the
prevalence
of
Colorado
Brown
Stain
in
the
mouths
of
native-born
residents.
He
would
write
later:
"I
spent
considerable
time
walking
on
the
streets,
noticing
the
children
in
their
play,
attracting
their
attention
and
talking
with
them
about
their
games,
etc.,
for
the
purpose
of
studying
the
general
effect
of
the
deformity.
I
found
it
prominent
in
every
group
of
children.
One
does
not
have
to
search
for
it,
for
it
is
continually
forcing
itself
on
the
attention
of
the
stranger
by
its
persistent
prominence.
This
is
much
more
than
a
deformity
of
childhood.
If
it
were
only
that,
it
would
be
of
less
consequence,
but
it
is
a
deformity
for
life."
Black
investigated
fluorosis
for
six
years,
until
his
death
in
1915.
During
that
period,
he
and
McKay
made
two
crucial
discoveries.
First,
they
showed
that
mottled
enamel
(as
Black
referred
to
the
condition)
resulted
from
developmental
imperfections
in
children's
teeth.
This
finding
meant
that
city
residents
whose
permanent
teeth
had
calcified
without
developing
the
stains
did
not
risk
having
their
teeth
turn
brown;
young
children
waiting
for
their
secondary
set
of
teeth
to
erupt,
however,
were
at
high
risk.
Second,
they
found
that
teeth
afflicted
by
Colorado
Brown
Stain
were
surprisingly
and
inexplicably
resistant
to
decay.The
two
researchers
were
still
a
long
way
from
determining
the
cause
of
Colorado
Brown
Stain,
but
McKay
had
a
theory
tucked
away
in
the
back
of
his
head.
Maybe
there
was,
as
some
local
residents
suggested,
an
ingredient
in
the
water
supply
that
mottled
the
teeth?
Black
was
skeptical;
McKay,
though,
was
intrigued
by
this
theory's
prospects.The
water-causation
theory
got
a
gigantic
boost
in
1923.
That
year,
McKay
trekked
across
the
Rocky
Mountains
to
Oakley,
Idaho
to
meet
with
parents
who
had
noticed
peculiar
brown
stains
on
their
children's
teeth.
The
parents
told
McKay
that
the
stains
began
appearing
shortly
after
Oakley
constructed
a
communal
water
pipeline
to
a
warm
spring
five
miles
away.
McKay
analyzed
the
water,
but
found
nothing
suspicious
in
it.
Nonetheless,
he
advised
town
leaders
to
abandon
the
pipeline
altogether
and
use
another
nearby
spring
as
a
water
source.McKay's
advice
did
the
trick.Within
a
few
years,
the
younger
children
of
Oakley
were
sprouting
healthy
secondary
teeth
without
any
mottling.
McKay
now
had
his
confirmation,
but
he
still
had
no
idea
what
could
be
wrong
with
the
water
in
Oakley,
Colorado
Springs,
and
other
afflicted
areas.The
answer
came
when
McKay
and
Dr.
Grover
Kempf
of
the
United
States
Public
Health
Service
(PHS)
traveled
to
Bauxite,
Arkansas-a
company
town
owned
by
the
Aluminum
Company
of
America-to
investigate
reports
of
the
familiar
brown
stains.
The
two
discovered
something
very
interesting:
namely,
the
mottled
enamel
disorder
was
prevalent
among
the
children
of
Bauxite,
but
nonexistent
in
another
town
only
five
miles
away.
Again,
McKay
analyzed
the
Bauxite
water
supply.
Again,
the
analysis
provided
no
dues.But
the
researchers'
work
was
not
done
in
vain.
McKay
and
Kempf
published
a
report
on
their
findings
that
reached
the
desk
of
ALCOA's
chief
chemist,
H.
V.
Churchill,
at
company
headquarters
in
Pennsylvania.
Churchill,
who
had
spent
the
past
few
years
refuting
claims
that
aluminum
cookware
was
poisonous,
worried
that
this
report
might
provide
fresh
fodder
for
ALCOA's
detractors.
Thus,
he
decided
to
conduct
his
own
test
of
the
water
in
Bauxite-but
this
time
using
photospectrographic
analysis,
a
more
sophisticated
technology
than
that
used
by
McKay.Churchill
asked
an
assistant
to
assay
the
Bauxite
water
sample.
After
several
days,
the
assistant
reported
a
surprising
piece
of
news:
the
town's
water
had
high
levels
of
fluoride.
Churchill
was
incredulous.
"Whoever
heard
of
fluorides
in
water,"
he
bellowed
at
his
assistant.
"You
have
contaminated
the
sample.
Rush
another
specimen."Shortly
thereafter,
a
new
specimen
arrived
in
the
laboratory.
Churchill's
assistant
conducted
another
assay
on
the
Bauxite
water.
The
result?
Photospectrographic
analysis,
again,
showed
that
the
town's
water
had
high
levels
of
fluoride
tainting
it.
This
second
and
selfsame
finding
prompted
Churchill
to
sit
down
at
his
typewriter
in
January,
1931,
and
compose
a
five-page
letter
to
McKay
on
this
new
revelation.
In
the
letter,
he
advised
McKay
to
collect
water
samples
from
other
towns
"where
the
peculiar
dental
trouble
has
been
experienced...
We
trust
that
we
have
awakened
your
interest
in
this
subject
and
that
we
may
cooperate
in
an
attempt
to
discover
what
part
'fluorine'
may
play
in
the
matter."McKay
collected
the
samples.
And,
within
months,
he
had
the
answer
and
denouement
to
his
30-year
quest:
high
levels
of
water-borne
fluoride
indeed
caused
the
discoloration
of
tooth
enamel.
New
Questions
Emerge
Hence,
from
the
curious
findings
of
Churchill's
lab
assistant,
the
mystery
of
the
brown
stained
teeth
was
cracked.
But
one
mystery
often
ripples
into
many
others.
And
shortly
after
this
discovery,
PHS
scientists
started
investigating
a
slew
of
new
and
provocative
questions
about
water-borne
fluoride.
With
these
PHS
investigations,
research
on
fluoride
and
its
effects
on
tooth
enamel
began
in
earnest.The
architect
of
these
first
fluoride
studies
was
Dr.
H.
Trendley
Dean,
head
of
the
Dental
Hygiene
Unit
at
the
National
Institute
of
Health
(NIH).
Dean
began
investigating
the
epidemiology
of
fluorosis
in
1931.
One
of
his
primary
research
concerns
was
determining
how
high
fluoride
levels
could
be
in
drinking
water
before
fluorosis
occurred.To
determine
this,
Dean
enlisted
the
help
of
Dr.
Elias
Elvove,
a
senior
chemist
at
the
NIH.
Dean
gave
Elvove
the
hardscrabble
task
of
developing
a
more
accurate
method
to
measure
fluoride
levels
in
drinking
water.
Elvove
labored
long
and
hard
in
his
laboratory,
and
within
two
years
he
reported
back
to
Dean
with
success.
He
had
developed
a
state-of-the-art
method
to
measure
fluoride
levels
in
water
with
an
accuracy
of
0.1
parts
per
million
(ppm).With
this
new
method
in
tow,
Dean
and
his
staff
set
out
across
the
country
to
compare
fluoride
levels
in
drinking
water.
By
1936,
he
and
his
staff
had
made
a
critical
discovery.
Namely,
fluoride
levels
of
up
to
1.0
ppm
in
drinking
water
did
not
cause
mottled
enamel;
if
the
fluoride
exceeded
this
level,
however,
fluorosis
began
to
occur.
Proof
That
Fluoride
Prevents
Caries
This
finding
sent
Dean's
thoughts
spiraling
in
a
new
direction.
He
recalled
from
reading
McKay's
and
Black's
studies
on
fluorosis
that
mottled
tooth
enamel
is
unusually
resistant
to
decay.
Dean
wondered
whether
adding
fluoride
to
drinking
water
at
physically
and
cosmetically
safe
levels
would
help
fight
tooth
decay.
This
hypothesis,
Dean
told
his
colleagues,
would
need
to
be
tested.In
1944,
Dean
got
his
wish.
That
year,
the
City
Commission
of
Grand
Rapids,
Michigan-after
numerous
discussions
with
researchers
from
the
PHS,
the
Michigan
Department
of
Health,
and
other
public
health
organizations-voted
to
add
fluoride
to
its
public
water
supply
the
following
year.
In
1945,
Grand
Rapids
became
the
first
city
in
the
world
to
fluoridate
its
drinking
water.The
Grand
Rapids
water
fluoridation
study
was
originally
sponsored
by
the
U.S.
Surgeon
General,
but
was
taken
over
by
the
NIDR
shortly
after
the
Institute's
inception
in
1948.
During
the
15-year
project,
researchers
monitored
the
rate
of
tooth
decay
among
Grand
Rapids'
almost
30,000
schoolchildren
.After
just
11
years,
Dean-
who
was
now
director
of
the
NIDR-announced
an
amazing
finding.
The
caries
rate
among
Grand
Rapids
children
born
after
fluoride
was
added
to
the
water
supply
dropped
more
than
60
percent.
This
finding,
considering
the
thousands
of
participants
in
the
study,
amounted
to
a
giant
scientific
breakthrough
that
promised
to
revolutionize
dental
care,
making
tooth
decay
for
the
first
time
in
history
a
preventable
disease
for
most
people.
A
Lasting
Achievement
Almost
30
years
after
the
conclusion
of
the
Grand
Rapids
fluoridation
study,
fluoride
continues
to
be
dental
science's
main
weapon
in
the
battle
against
tooth
decay.
Today,
just
about
every
toothpaste
on
the
market
contains
fluoride
as
its
active
ingredient;
water
fluoridation
projects
currently
benefit
over
200
million
Americans,
and
13
million
schoolchildren
now
participate
in
school-based
fluoride
mouth
rinse
programs.As
the
figures
indicate,
McKay,
Dean,
and
the
others
helped
to
transform
dentistry
into
a
prevention-oriented
profession.
Their
drive,
in
the
face
of
overwhelming
adversity,
is
no
less
than
a
remarkable
feat
of
science-an
achievement
ranking
with
the
other
great
preventive
health
measures
of
our
century.
Reprinted
from
Nation
Institute
of
Dental
and
Craniofacial
Research
http://www.nidcr.nih.gov/HealthInformation/OralHealthInformationIndex/Fluoride/StoryFluoride.htm
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